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Bovine cartilage explants were cultured over 21 days in the presence of two arthritogenic mAbs to CII CIIC1 or M2139, a non-arthritogenic mAb to CII CIIF4 or a control mAb GAD6.. All thr

Open Access

R927

Vol 7 No 5

Research article

Destructive effects of murine arthritogenic antibodies to type II

collagen on cartilage explants in vitro

Duncan E Crombie1, Muhammed Turer1, Beltzane Biurrun Zuasti1, Bayden Wood2,

Don McNaughton2, Kutty Selva Nandakumar3, Rikard Holmdahl3, Marie-Paule Van Damme1 and

Merrill J Rowley1

1 Department of Biochemistry and Molecular Biology, Monash University, Clayton, Victoria, Australia

2 Centre for Biospectroscopy and School of Chemistry, Monash University, Clayton, Victoria, Australia

3 Medical Inflammation Research, Lund University, Lund, Sweden

Corresponding author: Merrill J Rowley, Merrill.Rowley@med.monash.edu.au

Received: 6 Jan 2005 Revisions requested: 9 Feb 2005 Revisions received: 12 Apr 2005 Accepted: 10 May 2005 Published: 6 Jun 2005

Arthritis Research & Therapy 2005, 7:R927-R937 (DOI 10.1186/ar1766)

This article is online at: http://arthritis-research.com/content/7/5/R927

© 2005 Crombie et al.; licensee BioMed Central Ltd

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/

2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Certain monoclonal antibodies (mAbs) to type II collagen (CII)

induce arthritis in vivo after passive transfer and have adverse

effects on chondrocyte cultures and inhibit self assembly of

collagen fibrils in vitro We have examined whether such mAbs

have detrimental effects on pre-existing cartilage Bovine

cartilage explants were cultured over 21 days in the presence of

two arthritogenic mAbs to CII (CIIC1 or M2139), a

non-arthritogenic mAb to CII (CIIF4) or a control mAb (GAD6)

Penetration of cartilage by mAb was determined by

immunofluorescence on frozen sections and correlated with

changes to the extracellular matrix and chondrocytes by

morphometric analysis of sections stained with toluidine blue

The effects of mAbs on matrix components were examined by

Fourier transform infrared microspectroscopy (FTIRM) A

possible role of Fc-binding was investigated using F(ab)2 from

CIIC1 All three mAbs to CII penetrated the cartilage explants and CIIC1 and M2139, but not CIIF4, had adverse effects that included proteoglycan loss correlating with mAb penetration, the later development in cultures of an abnormal superficial cellular layer, and an increased proportion of empty chondrons FTIRM showed depletion and denaturation of CII at the explant surface in the presence of CIIC1 or M2139, which paralleled proteoglycan loss The effects of F(ab)2 were greater than those

of intact CIIC1 Our results indicate that mAbs to CII can adversely affect preformed cartilage, and that the specific epitope on CII recognised by the mAb determines both

arthritogenicity in vivo and adverse effects in vitro We conclude

that antibodies to CII can have pathogenic effects that are independent of inflammatory mediators or Fc-binding

Introduction

An experimental model of the human autoimmune disease

rheumatoid arthritis (RA) is provided by collagen-induced

arthritis (CIA), which is induced in animals after immunisation

with type II collagen (CII) [1,2], a major component of articular

cartilage The ensuing autoimmune response includes the

for-mation of antibodies to CII that, on transfer to nạve mice,

induce acute and destructive arthritis [3,4] Antibodies to CII

are present in the sera and synovial fluid of patients with RA

[5-7] and epitopes include those targeted by arthritogenic

antibodies from mice with CIA [8] Debate continues,

how-ever, on whether autoantibodies to CII in RA are actual contrib-utors to the pathogenesis, or merely reflect a reaction to cartilage degradation Although antibody-induced CIA can be transferred by combinations of mAbs [4,9], and also by certain single mAbs [4,10], not all mAbs to CII are arthritogenic, and arthritogenicity appears to be epitope specific [8] We postu-late that there are certain species of anti-CII autoantibodies that do cause cartilage damage by binding specifically to crit-ical structural regions on collagen fibrils that are sites of inter-action between CII and matrix components or chondrocytes Favouring this, arthritogenic mAbs to CII both inhibit collagen

fibrillogenesis in vitro [11] and adversely affect the cartilage

BSA = bovine serum albumin; CIA = collagen induced arthritis; CII = type II collagen; DMEM = Dulbecco's modified Eagle's medium; FCS = fetal

calf serum; FITC = fluorescein isothiocyanate; FTIRM = Fourier transform infrared microspectroscopy; IR = infrared; mAB = monoclonal antibody;

PBS phosphate buffered saline; RA = rheumatoid arthritis.

matrix and chondrocyte morphology in chondrocyte cultures

[12,13] On the other hand, cartilage is an avascular tissue in

which there is minimal collagen synthesis in adults [14];

more-over, antibodies penetrate cartilage so poorly [15] that they

may not be capable of disrupting a pre-existing cartilage

matrix

Accordingly, we examined the effects of different mouse mAbs

to CII on cultured cartilage explants and found that these not

only did penetrate and react with CII, but also had disruptive

effects on a pre-established cartilage matrix To help identify

changes in the cartilage matrix we used Fourier transform

infrared microspectroscopy (FTIRM), a technique by which

microscopic analysis is performed within the infrared (IR)

region of the spectrum IR microspectroscopy has been

pos-sible ever since the introduction of interferometers using

Fou-rier transformation some 30 years ago increased the sensitivity

of IR spectroscopy by orders of magnitude The spatial

resolu-tion of these instruments was limited to approximately 40 µm,

however, because the aperture of the microscope masked the

IR beam and essentially rejected a large proportion of the IR

radiation Additionally, the time involved in gathering spectra

over a large area was prohibitive With the introduction in the

late 1990s of focal plane array detectors, consisting of large

numbers of individual small detectors, both of these limitations

were overcome and multiple IR spectra over large areas can

now be taken close to the diffraction limit (10 µm at 1000 cm

-1) [16] With the instrument used in our studies, 4096 spectra

of a sample area 34 µm2 can be recorded simultaneously

within seconds Samples need to be thin (<10 µm) to allow

the IR beam to penetrate the whole section Here we have

used the technique of absorption/reflection by mounting thin

sections of tissue on slides coated with a thin layer of silver

and tin oxide that reflects IR light but transmits visible light

Accordingly, the reflected beam passes twice through the

sample, producing an array of IR spectra, and the visible light

transparency allows correlation of each IR spectrum with a

particular small area on the sample At IR wavelengths, the

spectra obtained are derived from vibrations within particular

chemical bonds and provide information on the chemical

com-position of the tissue without need for specialized

histochem-ical staining According to the method of analysis used,

images can be derived that represent the spectrum at a

partic-ular small region of the tissue, or chemical maps that represent

the relative concentration of a particular analyte in different

areas of the tissue FTIRM is applicable to both

paraffin-embedded tissue and cryosections, and thus can be

com-bined with standard histological techniques FTIRM has been

previously applied to studies of cartilage and the spectra of

collagens and proteoglycans are well defined [17-21]

Materials and methods

Monoclonal antibodies

CIIC1 [22] and M2139 [23] are arthritogenic mAbs that bind

to well defined conformational epitopes on the CB11 and

CB10 fragments of CII, respectively [8,10], and CIIF4 [22] is

a nonarthritogenic mAb that binds to a conformational epitope

on the CB9 fragment [8] CIIC1 and M2139 either individually,

or in combination, induce cartilage destruction after passive transfer [4] GAD6 was a control mAb that binds to an irrele-vant antigen glutamic acid decarboxylase [24] CIIC1, CIIF4 and GAD6 are IgG2a, and M2139 is IgG2b The mAbs CIIC1, M2139 and CIIF4 were derived from hybridomas derived from CII immunized mice and GAD6 was obtained from the Devel-opmental Studies Hybridoma Bank maintained by the Univer-sity of Iowa (Department of Biological Science, Iowa City, IA, USA) Hybridomas were cultured in miniPERM bioreactors (Heraeus Instruments, Hanau, Germany) in DMEM containing 10% (v/v) FCS (Trace Biosciences, Noble Park, Australia), 50 IU/ml penicillin and 50 mg/ml streptomycin as described pre-viously [12] The mAb quality was assessed using SDS-PAGE with 10% gels under reducing conditions, and the concentra-tion of the mAbs was determined by densitometry against a sample of known concentration

F(ab) 2 preparation

F(ab)2 was prepared from CIIC1 dialyzed against 0.2 M ace-tate buffer, pH 3.5, and digested with porcine pepsin at 37°C for 12 h The digestion was terminated by dialyzing against PBS, pH 7.4, overnight, and the digest was passed through a protein A column to remove undigested mAb or Fc The quality

of the digestion and the concentration of F(ab)2 was deter-mined by SDS-PAGE

Cultured bovine cartilage explants

Cartilage shavings from adult bovine metacarpal phalangeal joints were sliced into approximately 1 × 5 mm pieces; 50 mg

of cartilage was used for each sample The pieces were cul-tured at 37°C in the presence of 5% CO2 in 2 ml of DMEM containing 20% (v/v) heat-inactivated FCS containing 25 µg/

ml ascorbic acid The medium was changed every two days and fresh ascorbic acid and mAb were added at each change Cartilage explants were cultured with mAbs (50 µg/ml) or medium alone for periods up to 21 days To determine whether the effects were the result of Fc binding of the mAbs

to chondrocytes, the explants were cultured with 100 µg/ml of F(ab)2 from CIIC1, an equivalent amount of intact CIIC1, or medium alone for 7 or 14 days

Immunofluorescence to detect antibody penetration

After 14 days in culture, cartilage explants were collected and snap frozen in OCT compound (Tissue-Tek, Sakura Finetech-nical Co Ltd, Tokyo, Japan) using dry ice and isopentane Serial cryosections (5 µm) were stained with 0.1% toluidine blue in 30% ethanol, which stains the nuclei of the chondro-cytes and the proteoglycans within the matrix to examine mor-phology, or treated by immunofluorescence to detect antibody penetration For immunofluorescence, the sections were treated with 50 µl of type III hyaluronidase (Sigma, St Louis,

MO, USA) at 20 mg/ml in PBS for 30 minutes at room

temperature, washed with PBS and incubated with sheep

anti-mouse globulin conjugated with fluorescein isothiocyanate

(FITC) (Silenus, Hawthorn, Australia) diluted 1:150 in

carbon-ate buffer pH 8.6 containing 1% w/v BSA for 30 minutes at

room temperature To detect penetration of F(ab)2, the

sec-tions were incubated with a goat antibody to mouse F(ab)2

(ICN Biomedicals Inc., Aurora, OH, USA) diluted 1:2000 in

PBS with 1% w/v BSA for 1 h, followed by incubation with

rab-bit anti-goat Ig, conjugated with Alexa 488 (Molecular Probes,

Eugene, OR, USA) diluted 1:400 in carbonate buffer, pH 8.6,

with 1% w/v BSA The slides were then mounted with 90% v/

v glycerol in PBS and observed microscopically

Histomorphometry

On selected days, cartilage explants were fixed in 4%

parafor-maldehyde, embedded in paraffin, and 5 µm sections were cut

and stained with either toluidine blue or haemotoxylin and

eosin Histomorphometry was performed on MCID software

(M4 3.0 Rev 1.1; Imaging Research Inc., St Catherines,

Ontario, Canada) Images were captured at 200 ×

magnifica-tion from three to five separate pieces of tissue for each

cul-ture At each timepoint, the mean loss of toluidine blue stain,

mean chondron size, number of cells per mm2 and the

percent-age of empty chondrons was determined To determine the

loss of toluidine blue staining from the section, the auto-select

tool was used to designate and create a line at the point that

the loss of staining ended; using the two-point straight-line

measurement tool, the distance of loss was measured from the

edge of the tissue, excluding any superficial layering, through

to the line created by the auto-select tool The measurement

was performed six times on each image captured MCID

soft-ware was likewise used to measure the penetration of mAbs in

the frozen sections For chondron size, individual chondrons

were manually outlined using the MCID software, which then

calculated chondron area An average of 24 chondrons (range

± 13) that contained cells (usually only one cell per chondron)

were counted from each image, and empty chondrons were

counted separately to calculate the percentage of empty

chondrons The number of cells per mm2 was calculated by

counting the number of cells within an area measured by the

MCID software

Preparation of purified type II collagen and crude extract

of proteoglycan for analysis by FTIRM

Bovine cartilage was treated with 4 M guanidine-HCl (Sigma)

The resultant crude proteoglycan mixture, which contained

predominantly aggrecan, was dialysed extensively against

dis-tilled water to remove guanidine-HCl and freeze dried CII was

prepared from the extracted cartilage by pepsin digestion and

differential salt precipitation as previously described [7] Ultra

pure high molecular weight hyaluronan was provided by Garry

Brownlee (Department of Biochemistry and Molecular

Biol-ogy, Monash University, Clayton, Victoria, Australia)

Measurement of changes in the composition of the matrix by Fourier transform infrared microspectroscopy

For the present study, 5 µm sections of paraffin embedded tis-sue taken at day 14 were placed onto MirrIR low-e microscope slides (Kevley Technologies, Chesterland, OH, USA), and adjacent sections were collected for staining with toluidine blue Sections were dewaxed and allowed to air dry To exam-ine the spectra of CII, a crude proteoglycan extract and hyaluronan, 20 µl of each component was allowed to dry in air

on a MirrIR microscope slide FTIRM images were recorded with a 'Stingray' Digilab FTS 7000 series spectrometer (Digi-lab, Varian, Mulgrave, Victoria, Australia) coupled to a UMA

600 microscope equipped with a 64 × 64 focal plane array detector

For each spectrum, 16 scans were co-added at a resolution of

6 cm-1 The spectra were preprocessed using purpose-built software compiled using Matlab (The Mathworks Inc., Natick,

MA, USA) [25] This processing entailed a linear base line cor-rection and vector normalization This data matrix was then exported into Cytospec Software for Infrared Spectral Imaging (Cytospec, Inc, http://www.cytospec.com/, Berlin, Germany) and a 'quality test' was performed to remove spectra with poor signal-to-noise ratios and spectra containing obvious artifacts Chemical maps were generated from the integrated intensities

of specific functional groups identified in the spectra Using the same software, 10 spectra from the antibody-exposed exterior of the explant, and from the interior of the explant, were extracted from the chemical maps The mean spectrum for each was calculated to assess the effects of antibody penetration

In the present study, we examined peaks characteristic of col-lagen and proteoglycans An FTIRM spectrum of proteogly-cans demonstrates peaks within the region of 1175-960 cm-1

derived from carbohydrate moieties, and at 1241 cm-1 derived from sulphate of the sulphated glycosaminoglycan side-chains [17,18] The collagen spectrum shows a characteristic triplet

of peaks at 1203, 1234 and 1280 cm-1 but this region includes the peak at 1240–1245 cm-1 characteristic of sul-phates [17,18] Accordingly, we examined the amide 1 peak that represents total protein, as a measure of the collagen con-tent; the amide 1 peak for native collagen occurs at about

1666 cm-1, with a shift to a lower wave number (cm-1) on dena-turation [21] or after collagenase treatment [26] In the present study, these spectral shifts were confirmed using purified pep-sin-digested CII prepared from bovine nasal cartilage [7], before and after heat denaturation at 50°C, and using explanted bovine cartilage treated with collagenase for 20 minutes before fixation and processing as described above

Statistical analysis

Statistical analyses were performed using Statistica for Win-dows, Version 4.5 (Statsoft Inc., Tulsa, OK, USA) ANOVA was performed to determine whether there were significant

differences between groups, and Student's t-test, or the

non-parametric Mann Whitney U-test, were used to compare

indi-vidual differences P < 0.05 was considered significant

Results

Immunofluorescence to detect antibody penetration

Each of the mAbs to CII, whether arthritogenic (CIIC1 and

M2139) or not (CIIF4), penetrated the extracellular matrix

dur-ing culture and remained bound to the tissue, as demonstrated

by the areas of fluorescence around the edge of the explant, in

contrast to the control mAb GAD6 (Fig 1a–d) The distance

(mean ± SD) of penetration at the surface of the cartilage was

48 ± 8 µm for CII-F4, 33 ± 8 µm for CIIC1 and 86 ± 8 µm for

M2.139 The F(ab)2 of CIIC1 completely penetrated the tissue

Morphology of cartilage explants

As seen by light microscopy and toluidine blue staining,

explants cultured in medium alone, or in the presence of either

GAD6 or CIIF4, remained healthy even up to 21 days in

cul-ture (Fig 2a), and stained strongly with toluidine blue In

con-trast, the two arthritogenic mAbs, CIIC1 and M2139, caused

profound changes in the explant structure, progressively over

time Both mAbs, and particularly M2139, had effects on the

matrix These included loss of toluidine blue staining from the

surface of the tissue and, after 14 days in culture, development

of a layer of cells on the surface of the explant (Fig 2b, c) Chondrocytes developed changes resembling hypertrophy and there was a measurable increase in the proportion of empty chondrons Notably, the non-arthritogenic mAb CIIF4 induced none of these changes

To quantify changes in the explant structure, the loss of prote-oglycans and percentages of empty chondrons were analyzed using culture samples collected at days 3, 7, 10, 14, 17 and

21 There were no significant differences by ANOVA in any of the measurements made between explants cultured individu-ally with GAD6, CIIF4 or no antibody For explants cultured with CIIC1, and particularly M2139, however, there was a sig-nificant increase in the loss of toluidine blue staining from the surface of the tissue over the period of culture that was not seen in the control groups The controls, exemplified by CIIF4,

a loss of staining similar to that for CIIC1 at day 4, but thereaf-ter there was clear evidence of recovery (Fig 3a) CIIC1, and particularly M2139, exhibited an increase in percentage of empty chondrons with increasing time in culture (Fig 3b) There were no significant differences between either of the arthritogenic mAbs, CIIF4 or other controls in the number of cells per mm2, or in the size of the cells

Figure 1

Immunofluorescence showing the penetration of the three anti-CII antibodies

Immunofluorescence showing the penetration of the three CII antibodies: (a) CIIF4, (b) CIIC1 and (c) M2139 The area of colour indicates anti-body binding (d) The control mAb (GAD6) shows no binding to the cartilage.

Figure 2

A toluidine blue stained sections of cartilage

A toluidine blue stained sections of cartilage (a) Cartilage cultured for 7 days shows an evenly stained matrix with typical rounded chondrocytes Sections of cartilage incubated for (b) 7 days and (c) 14 days with M2139 show abnormal matrix morphology with the loss of toluidine blue, the

development of a cellular layer at the surface and the development of hypertrophic chondrocytes.

Effect of F(ab) 2 from CIIC1 on cartilage explants

To determine whether the changes observed were the result

of direct antibody binding, or whether they resulted from

bind-ing of antibody complexes with Fc receptors on the surface of

chondrocytes, the effects of the F(ab)2 fragment of CIIC1 were

compared with those of intact CIIC1 after 7 or 14 days in

cul-ture As seen by immunofluorescence, the F(ab)2 was able to

penetrate a greater distance into the tissue than intact CIIC1

(data not shown), and the F(ab)2 caused greater disruption of

architecture Also there was greater loss of toluidine blue

staining than for CIIC1

Fourier transform infrared spectra of cartilage

components

The IR spectrum of a pure chemical is derived from vibrations

within particular chemical bonds, and thus can provide a

unique fingerprint for that chemical In the case of complex bio-logical systems, the spectrum derived is a composite of the individual spectra of the components of that tissue, and analy-sis of chemical changes depends on knowledge of the spectra

of individual components To validate the use of FTIRM in the present study, the spectra of the major cartilage components, CII, proteoglycan and hyaluronan were examined (Fig 4a); each component had its own unique spectrum, establishing the ability of FTIRM to distinguish between these components

A combination of the spectra according to proportions that would represent those in articular cartilage, 55% collagen, 40% proteoglycan and 5% hyaluronan, generated a compos-ite spectrum that resembled that of normal articular cartilage (Fig 4b)

Figure 3

Differences in the loss of proteoglycan and chondrocyte between

cul-tures incubated with different mABs

Differences in the loss of proteoglycan and chondrocyte between

cul-tures incubated with different mABs (a) Loss of toluidine blue staining

between cultures incubated with CIIF4 (white) and cultures incubated

with CIIC1 (light grey) and M2139 (dark grey) over the course of 21

days (b) The number of empty chondrons expressed as a percentage

of the total number of chondrons, indicating the loss of chondrocyte

from the extracellular matrix The columns represent the mean of each

measurement and error bars indicate 1 standard deviation The asterix

represents p < 0.05.

Figure 4

FTIRM spectra of the major cartilage components CII, proteoglycan and hyaluronan

FTIRM spectra of the major cartilage components CII, proteoglycan and

hyaluronan (a) Typical spectra for CII, crude proteoglycan extract and hyaluronan (b) An artificial spectrum that resembles normal articular

cartilage generated by combining appropriate proportional amounts of the spectra of CII (55%), crude proteoglycan extract (40%) and hyaluronan (5%) The amide 1 peak from 1600–1700 cm -1 represents the total protein content, the triplet of peaks from 1200–1300 cm -1 are characteristic of the spectrum of collagen, and the peaks in the region 960–1175 cm -1 result from sugars in the proteoglycans and

hyaluronan.

Chemical changes in cartilage matrix detected by Fourier

transform infrared microspectroscopy

The loss of proteoglycans observed from toluidine blue

stained sections was confirmed by FTIRM Information on

pro-teoglycan distribution in the explants was generated by

creat-ing a chemical map made by integratcreat-ing the area under the

peaks in the 1175-960 cm-1 region Comparisons were made

between serial sections of cartilage cultured in the presence

of the control GAD6 (Fig 5), stained with toluidine blue to

show the distribution of proteoglycans (Fig 5a), or processed

by FTIRM (Fig 5b), in which the regions with the highest

con-centration of proteoglycans are shown as red, and the lowest

concentrations are shown as blue In the section processed by

FTIRM, the distribution of proteoglycans across the section

was relatively even, with minimal loss of proteoglycans from

the surface of the explant This was confirmed by comparing

mean spectra from the surface and middle of the section (Fig

5c), although there was a slight reduction in proteoglycans at

the edge of the section as shown by a reduction in the peak

absorbance from the sugars (at 1072 cm-1) and a reduction in

a peak at 1241 cm-1 that is representative of the sulphate in

the chondroitin and keratan sulphates of proteoglycans (Table

1) The distribution of proteoglycans and the spectra obtained

for GAD6 were characteristic of those obtained for cartilage

cultured without antibody

In contrast, there were marked differences in the distribution

of proteoglycans across the tissue for explants cultured with

each of the mAb to CII The mean spectra taken at the surface

of the section as well as those from the middle also differed

(Figs 6a–f and 7a–c; Table 1) The concentration of

proteogly-cans from the middle of the tissue, beyond the penetration of

the mAb, did not differ from the controls, as judged by the height of the peaks at 1175-960 cm-1, and peaks at 1203,

1234 and 1280 cm-1; therefore, spectra (n = 10) from the inte-rior of the cartilage treated with the four mAbs were combined (Table 1) There was, however, a reduction in the concentra-tion of proteoglycans at the surface of the tissue based on the decrease in the peak at 1072 cm-1, and a corresponding decrease in the sulphate peak at 1241 cm-1 that was much greater for CIIC1 and M2139 than for CIIF4 (Table 1) In addi-tion, at the surface of the tissue in each of the explants treated with the mAbs to CII, but not with GAD6, there was a decrease in absorbance and a spectral shift in amide 1, from

a peak at 1666 cm-1 to below 1660 cm-1 (Table 1) These results are consistent with the spectral shifts in the amide 1 peak, obtained after heat denaturation of purified CII (from

1666 to 1652 cm-1) and with surface changes observed after treatment of cartilage with collagenase (from 1668 to 1653

cm-1)

The F(ab)2 treated cartilage showed a uniform and substantial loss of proteoglycan across the toluidine blue-stained tissue (Fig 7d, e); this was confirmed by the mean spectra from the surface and from the middle of the section (Fig 7f) There was almost complete loss of the proteoglycan peak between 1175-960 cm-1, a marked reduction in the sulphate peak at

1241 cm-1, and the peaks at 1203, 1234 and 1280 cm-1, and

a striking decrease and spectral shift to 1644 cm-1 in the amide 1 peak, indicative of denaturation and loss of CII from the matrix, across the whole tissue (Table 1)

Figure 5

Distribution of proteoglycans in the cultured explants

Distribution of proteoglycans in the cultured explants (a) Toluidine blue stained sections cultured for 14 days with GAD6 (b) Chemical map derived

using FTIRM showing the proteoglycan region (960–1175 cm -1 ) The chemical maps show the distribution and relative concentrations of

proteogly-cans; the least concentrated areas are shown as blue and the most concentrated areas that are shown as red (c) The spectra shown are the mean

of 10 measurements taken from either the central areas (red line) or near the surface of the tissue (blue line) The error bars represent 1 standard deviation at those points in the spectra The amide 1 region, which represents the total protein content of the tissue, is from 1600–1700 cm -1

Discussion

Human RA and its animal model CIA are complex diseases in

which both the immune response and subsequent

inflamma-tion are important determinants of cartilage destrucinflamma-tion The

effector phase of CIA, evident two to three days after passive

transfer of anti-CII to healthy mice has been studied

exten-sively [3,4,9,10,27,28], and the development of collagen

anti-body-induced arthritis provides an informative in vivo model in

which inflammatory processes can be examined in the

absence of an inductive immune response [4] Little is known,

however, about any direct effects of antibody on the target

car-tilage tissue and the contribution of this to the ensuing disease

process Our study has investigated the effects of two such

arthritogenic mAbs to CII, CIIC1 and M2139, on cultured

bovine cartilage explants and compared the results with a

non-arthritogenic mAb to CII, CIIF4, and to an irrelevant mAb,

GAD6, in the absence of inflammatory mediators known to

dominate the effector phase of CIA Both arthritogenic and

non-arthritogenic mouse mAbs to CII were shown by immun-ofluorescence to penetrate cartilage and bind strongly to the matrix, but only the former had adverse effects Such binding caused loss and denaturation of collagen Loss of proteogly-cans was observed both by light microscopy as loss of toluid-ine blue staining of the matrix, and changes in the chemical map by FTIRM Concomitantly, we observed the appearance

of 'empty' chondrons in the cartilage, and the development of

a superficial cell layer of morphologically non-descript cells within a matrix that reacted strongly to immunofluorescence at day 14 of culture Such effects could explain the observation that not all antibodies to CII are arthritogenic, and pathogenic-ity may depend on the particular epitope(s) recognized [8,29]

FTIRM has emerged over the last 10 years as a most effective means of identifying and quantifying differences between defined areas or single points of histological specimens, and the present study illustrates its use for the examination of

Figure 6

Distribution of proteoglycans in the explants cultured with CIIF4 or M2139

Distribution of proteoglycans in the explants cultured with CIIF4 or M2139 Toluidine blue stained sections cultured for 14 days with (a) CIIF4 or (d) M2139 are shown alongside (b, e) chemical maps showing proteoglycan distribution and (c, f) FTIRM spectra from the central areas (red line) and

near the surface of the tissue (blue line) The error bars represent 1 standard deviation at those points in the spectra.

changes in the collagen content of the cartilage that would

otherwise require complex quantitative biochemical analysis

[12,30] or multiple immunohistochemical studies [31] The

shift in the amide 1 peak in the areas penetrated by antibody

in explants cultured with both the arthritogenic mAbs (CIIC1

and M2139) and the non-arthritogenic mAb CIIF4 is

consist-ent with changes that occur during denaturation of collagen

[21] or during collagenase treatment [26], and that are taken

to represent an unwinding of the triple helical conformation

Notably, in the same areas, a reduction in the levels of collagen

was shown by a reduction in the collagen triplet between

1300-1200 cm-1 Finally, as seen by the reduction of peaks in

the range 1175-960 cm-1, FTIRM confirmed the reduction of

proteoglycans shown by toluidine blue staining that occurred

around the surface of the cartilage explants exposed to CIIC1

and M2139, and the complete loss of proteoglycan in explants

exposed to F(ab)2 of CIIC1 The changes seen in vitro are sim-ilar to changes that occur in cartilage in vivo after passive transfer of mAbs, although such changes in vivo are assumed

to be due to the effects of degradative enzymes produced by the accompanying inflammation It is of interest that loss of proteoglycan is an early marker of the cartilage disruption that occurs in both osteoarthritis [32] and RA [33], in which it is attributed to matrix metalloproteinases and aggrecanases (the ADAMTS or 'a disintegrin and metalloproteinase with throm-bospondin motif' family of proteases) [31,32] that are released following disruption of the molecular interactions between matrix constituents This loss of the proteoglycans, which pro-vide 'cushioning' of the cartilage in the joint, in turn allows a greater susceptibility to damage from compressive forces and greater penetration of degradative molecules

Figure 7

Distribution of proteoglycans in the explants cultured with CII-C1 or F(ab)2 from CII-C1

Distribution of proteoglycans in the explants cultured with CII-C1 or F(ab)2 from CII-C1 Toluidine blue stained sections cultured for 14 days with (a) CII-C1 or (d) F(ab)2 are shown alongside (b, e) chemical maps showing proteoglycan distribution and (c, f) FTIRM spectra from the central areas

(red line) and near the surface of the tissue (blue line) Note that the proteoglycan levels are lower and the amide 1 peak has shifted across the whole of the F(ab)2 treated tissue The error bars represent 1 standard deviation at those points in the spectra.

The changes in the matrix at the surface of the cartilage

observed in the explants cultured with the arthritogenic mAbs

CIIC1 and M2139 accompanied appearances of 'empty'

chondrons in the cartilage Although apoptosis is a common

secondary effect of cartilage disruption, it is difficult to

meas-ure in cartilage We therefore used loss of chondrocytes from

the matrix as a measure of cell death, as has been done before

[34] Cultures with CIIC1, and particularly M2139,

demon-strated increasing numbers of empty chondrons over time and,

in many cases, the same sections showed chondrons

contain-ing several cells, which is suggestive of hyperplasia as a

com-pensatory response to mAb-mediated cartilage damage By

day 14 of culture the surface of explants exposed to CIIC1 or

M2139 had a superficial layer of morphologically non-descript

cells within a scanty matrix Presumably this cell layer, having

lost the proteoglycans, was composed of collapsed cartilage

Strong staining by immunofluorescence, which demonstrated

the presence of CII, provided further evidence that this layer

had a cartilaginous origin Its appearance was suggestive of

the fibrous pannus characteristically described in rheumatoid

arthritis, which has also been shown to contain CII, and is also

possibly derived from chondrocytes [35,36]

The use of F(ab)2 demonstrated that the effects we observed

with cultured explants is not Fc mediated Evidence that

chondrocytes express Fc receptors is limited, but non-specific

Fc-mediated binding of immune complexes to chondrocytes

has been reported to stimulate matrix metalloproteinase

pro-duction and propro-duction of interleukin 1 by chondrocytes [37]

While Fc receptors have been shown to be important in CIA

[38,39], particularly in inflammation induction and in the

pas-sive transfer of antibody-mediated disease [10], successful

treatment of inflammation can still leave an ongoing problem of

continuing joint destruction [40-42] In the present study, the effect of the F(ab)2 was much greater than that of a corre-sponding molar concentration of intact CIIC1 This is because the smaller size of the F(ab)2 would allow it to penetrate more deeply into the tissue; indeed, in F(ab)2-treated sections, there was a correspondingly greater loss of proteoglycans and decreased collagen content as seen by FTIRM Alternatively, if Fc-receptor binding were, in fact, a normal physiological method of removing immune complexes [43], mAb bound to collagen in the cultured tissue could persist, and the total amount of mAb could increase with each change of medium

If this is the case, then the greater effects caused by the F(ab)2 would truly represent the effect of having higher amounts of antibody

We emphasize that all of the changes in this study have been

observed in vitro without the confounding influences of

inflam-mation, complement and other immunological mediators present in a CIA or RA- affected joint, and that the use of a F(ab)2 fragment of the arthritogenic mAb excludes the possi-bility of these effects being due to Fc binding Presently, the assessment of cartilage damage in CIA relies on scoring joint damage, histological abnormalities and measuring release of cartilage breakdown products such as cartilage oligomeric matrix protein [44] This could mask the damaging effect of antibody binding; denaturation of collagen in the matrix that leads to disruption in the organization of the matrix Our results

suggest that the effects of arthritogenic mABs on de novo

syn-thesis of cartilage matrix that we have previously reported from studies on chondrocyte cultures [12] are paralleled by degra-dative effects on preexisting cartilage These include not only the loss of matrix, but also loss of chondrocytes and denatur-ation of collagen fibrils and would contribute to direct and

on-Table 1

Absorbance data from FTIRM used to examine levels of proteoglycan and collagen from different cultures

a Absorbance from the proteoglycan peak at 1072 cm -1 is representative of sugars b Absorbance from the proteoglycan peak at 1242 cm -1 is

representative of sulphated glycosaminoglycans c The amide 1 peak provides a measure of total protein, predominantly collagen Note the change

in the location of the amide 1 peak in the presence of mAbs to CII, consistent with the change from 1666–1668 cm -1 to 1652–1653 cm -1

observed after heat denaturation of the collagen helix, or collagenase treatment (see text) Results shown are mean ± SD d Ten spectra from the

interior of the cartilage treated with the four antibodies were combined.

going cartilage loss that is independent of any injurious effect

of inflammation This is in accord with the likelihood that loss

of cartilage in RA, seen radiologically as joint space narrowing,

may be due to a different process than that responsible for

development of erosions [45]

Conclusion

This study has important connotations for our understanding

of the pathogenesis of RA Autoantibodies to collagen occur

in RA [5-7], bind to cartilage and can be released from immune

complexes within the cartilage by treatment with collagenase

[46], and have specificity for epitopes that are arthritogenic in

mice [8] Both CIA and RA are complex polygenic diseases in

which the gross pathology results from cell- and

antibody-mediated inflammation We have also demonstrated that

arthritogenic mAbs to CII can contribute directly to cartilage

destruction, which implies the involvement of

non-inflamma-tory as well as inflammanon-inflamma-tory components in the disease

proc-ess It is even possible that injurious effects of antibody on

articular cartilage may precede and even initiate subsequent

inflammatory events that contribute to ultimate joint

destruc-tion, and provides a further rationale for the successful use of

combination therapies [47]

Competing interests

The authors declare that they have no competing interests

Authors' contributions

DEC carried out explant and hybridoma cultures,

immunofluo-rescence, performed MCID and FTIRM analysis and drafted

the manuscript MT developed the explant culture system and

performed the initial experiments BBZ prepared F(ab)2 and

tested its effects on cultures BW and DMcN were

responsi-ble for the analysis and interpretation of the FTIRM results

KSN and RH provided the monoclonal antibodies used in the

study, and have revised the manuscript critically for intellectual

content based on experience with the in vivo animal model.

MPVD provided expertise with chondrocyte and explant

cul-tures, participated in the design of the study, and helped draft

the manuscript MJR conceived of the study, participated in its

design and coordination, performed statistical analysis and

helped draft the final manuscript All authors read and

approved the final manuscript

Acknowledgements

We thank Ian Boundy for his expert histological assistance, Senga

Whit-tingham, Fatemah Aminrahmadi and Ian Mackay for helpful discussions

The work was supported by grants from the National Health and Medical

Research Council of Australia and the Arthritis Foundation of Australia.

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